CN201904163U - Optical fiber composite medium-voltage reeled cable used for port machinery - Google Patents
Optical fiber composite medium-voltage reeled cable used for port machinery Download PDFInfo
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- CN201904163U CN201904163U CN 201020686598 CN201020686598U CN201904163U CN 201904163 U CN201904163 U CN 201904163U CN 201020686598 CN201020686598 CN 201020686598 CN 201020686598 U CN201020686598 U CN 201020686598U CN 201904163 U CN201904163 U CN 201904163U
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- cable
- optical fiber
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- conductor
- fiber composite
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Abstract
The utility model discloses an optical fiber composite medium-voltage reeled cable used for port machinery, belongs to the field of cables, and aims to solve the problem of low mechanical strength of the cables in the prior art. The optical fiber composite medium-voltage reeled cable comprises a cable core, a filling core arranged in the internal gaps of the cable core, an inner sheath extruded at the periphery of the cable core, a nylon reinforcing layer wrapped outside the inner sheath, and an outer sheath extruded outside the nylon reinforcing layer, wherein the cable core is formed by stranding three insulated core wires, a first grounding wire, a first optical fiber cable, a first fiber filler, a second grounding wire, a second optical fiber cable and a second fiber filler; the first grounding wire, the first optical fiber cable, the first fiber filler, the second grounding wire, the second optical fiber cable and the second fiber filler are spaced in the gaps around the three insulated core wires; and each insulated core wire comprises a conductor which is formed by stranding a plurality of copper wire bundles to form strands and then stranding the strands, an inner shielding layer wrapped outside the conductor, an ethylene-propylene rubber insulating layer wrapped outside the inner shielding layer, an insulating shielding layer wrapped outside the insulating layer, and a tinned copper wire braid ply wrapped outside the insulating shielding layer. By adopting the multi-strand conductor, the multi-layer extruded structure and the filling cores which are positioned in the internal gaps of the core wire conductor bundles, the mechanical strength of the cable is increased. The optical fiber composite medium-voltage reeled cable can be applied to the port machinery.
Description
Technical field
The utility model relates to a kind of cable, particularly a kind of port machine writing that surpasses all the others dish cable in the Optical Fiber Composite.
Background technology
Fast development along with China's water transportation industry, the dynamics of investment of port construction is progressively accelerated, riverine, coastal cargo throughput of port is risen progressively year by year, thereby driven harbour cargo handling equipment to scientific, the development of automation aspect is particularly active, emerged in large numbers all kinds of harbours loop wheel machine of many novel high-performances, because the needs of loop wheel machine operation principle, the motor power transmission line then needs frequent lifting in the loop wheel machine, be wound on back and forth on the reel of loop wheel machine, this just all has higher requirement to the flexibility and the mechanical strength of cable, simultaneously, cable there is certain communications rate requirement.In the prior art, a kind of naval vessel and ocean engineering high flexible cable are arranged, publication number is: CN201549253U, comprise the cored wire conductor of forming by some tinned copper wires, tinned copper wire is divided into soft dried bundle, the equidirectional stranded synnema of every Shu Zishen constitutes strand, and all strand is twisted into cored wire conductor in the other direction again, and cored wire conductor is extruded with insulating barrier outward.This cable adopts equidirectional disposable synnema, form strand, strand carries out multiple strand in the other direction then, avoided tinned copper wire occur to jump the silk local thin phenomenon of crossing that causes insulating, caused insulation breakdown, made its pliability good, its weak point is: this cable has only extruded insulating barrier outside cored wire conductor, make that the mechanical strength of cable itself is low, the power that stretched effect cable is fragile, and effectiveness is low.
The utility model content
The purpose of this utility model is to provide a kind of port machine with writing that surpasses all the others dish cable in the Optical Fiber Composite, makes cable machinery intensity height, and pliability is good, effectiveness height, long service life.
For solving above technical problem, the utility model provides port machine writing that surpasses all the others dish cable in the Optical Fiber Composite, after comprising that some copper wire bundles are twisted into strand, strand carries out the conductor that multiple strand forms again, described conductor is coated with internal shield, described internal shield is coated with ethylene propylene rubber insulated layer, and described insulating barrier is coated with insulation screen, and insulation screen is coated with tincopper fuse wire braided armor becomes the insulation heart yearn; Three thoroughly do away with the edge heart yearn is provided with spaced earth connection, optical fiber cable, fiber filling in the slit on every side, and described earth connection, optical fiber cable, fiber are filled, three described insulation heart yearns are twisted into and are cable core; The intermediate gaps of described cable core is provided with filled core, and described cable core periphery is extruded with inner sheath, and inner sheath is coated with cotton synthetic fibre reinforced layer, and cotton synthetic fibre reinforced layer is extruded with oversheath outward.
Compared with prior art, the beneficial effects of the utility model are: the utility model carries out the conductor that multiple strand is made after adopting and earlier some copper wire bundles being twisted into strand again, has avoided copper wire silk to occur jumping and has caused insulation breakdown; Adopt conductor to extrude screen outward, screen is provided with insulating barrier outward, and insulating barrier is provided with insulation screen outward, and insulation screen is provided with the sandwich construction of braid outward, avoids causing cable to break because of Cable Bending Radius is too small, has improved the pliability of heart yearn bundle; Be arranged on the filled core of insulated electric conductor intermediate gaps, further improved the anti-mechanical pulling force of cable, the anti-mechanical pulling force of the cotton synthetic fibre reinforced layer that is provided with between inner sheath and the oversheath is effective, thereby has improved the mechanical strength of cable; Be arranged on the fiber optic cables in the slit around the cored wire conductor, improved the transmission rate of signal.The utility model can be used in the machine of port.
As improvement of the present utility model, described brass wire diameter is 0.4mm.Guaranteed the pliability of cable.
As further improvement of the utility model, lay ratio was 8~10 when described copper wire bundle twisted, and lay ratio was not more than 11 when described strand was stranded, and lay ratio was not more than 12 when described insulation cored wire conductor was stranded.Can further improve the pliability of cable.
As further improvement of the utility model, described screen, insulation shielding layer material are flexible nonmetal semiconductive material.In the shielding properties that strengthens between conductor, guaranteed the pliability of cable.
As further improvement of the utility model, described inner sheath, jacket material are wear-resisting high-modulus neoprene.Improve the mechanical strength of sheath, thereby improved the mechanical strength of cable.
Description of drawings
Fig. 1 is the utility model structural representation.
Among the figure: 1 oversheath, 2 cotton synthetic fibre reinforced layers, 3 inner sheaths, 4 braids, 5 insulation screens, 6 insulating barriers, 7 earth connections, 8 filled cores, 9 screens, 10 cored wire conductors, 11 optical fiber cables, 12 fibers are filled.
Embodiment
As shown in Figure 1, be port machine writing that surpasses all the others dish cable in the Optical Fiber Composite, after comprising that some copper wire bundles are twisted into strand, strand carries out the conductor 10 that multiple strand forms again, brass wire diameter is 0.4mm, lay ratio is 8~10 during the copper wire bundle strand, lay ratio was not more than 11 when strand was stranded, lay ratio was not more than 12 when insulation cored wire conductor 10 was stranded, conductor 10 is coated with internal shield 9, and internal shield 9 is coated with ethylene propylene rubber insulated layer 6, and insulating barrier 6 is coated with insulation screen 5, screen, insulation screen 5 materials are flexible nonmetal semiconductive material, and insulation screen 5 is coated with tincopper fuse wire braided armor 4 becomes the insulation heart yearn; Three thoroughly do away with the edge heart yearn is provided with spaced earth connection 7, optical fiber cable 11, fiber filling 12 in the slit on every side, and described earth connection 7, optical fiber cable 11,12, three described insulation heart yearns of fiber filling are twisted into and are cable core; The intermediate gaps of cable core is provided with filled core 8, and the cable core periphery is extruded with inner sheath 3, and inner sheath 3 is coated with cotton synthetic fibre reinforced layer 2, is extruded with oversheath 1 outside the cotton synthetic fibre reinforced layer 2, and inner sheath 3, oversheath 1 material are wear-resisting high-modulus neoprene.
The utility model carries out the conductor that multiple strand is made after adopting and earlier some copper wire bundles being twisted into strand again, has avoided copper wire silk to occur jumping and has caused insulation breakdown; Adopt sandwich construction, avoid causing cable to break, improved the pliability of heart yearn bundle because of Cable Bending Radius is too small; Be arranged on the filled core 8 of insulated electric conductor intermediate gaps, further improved the anti-mechanical pulling force of cable, the cotton synthetic fibre reinforced layer 2 anti-mechanical pulling force that are provided with between inner sheath 3 and the oversheath 1 are effective, thereby improved the mechanical strength of cable.In order to guarantee the pliability of cable, brass wire diameter is 0.4mm; Suitable lay ratio can further improve the pliability of cable; The screen 9 of flexible nonmetal semiconductive material, insulation screen 5 can guarantee the shield effectiveness of 10 of cored wire conductors, also can improve the pliability of cable, select for use wear-resisting high-modulus chloroprene rubber material to make sheath, have further guaranteed the mechanical strength of cable; Be arranged on the effectiveness that slit optical fiber cable 11 around the cored wire conductor has improved cable, fiber is filled the mechanical performance that has strengthened cable.
In addition to the implementation, the utility model can also have other execution modes.All employings are equal to the technical scheme of replacement or equivalent transformation formation, all drop in the protection range of the utility model requirement.
Claims (5)
1. the port machine is with writing that surpasses all the others dish cable in the Optical Fiber Composite, it is characterized in that: after comprising that some copper wire bundles are twisted into strand, strand carries out the conductor that multiple strand forms again, described conductor is coated with internal shield, described internal shield is coated with ethylene propylene rubber insulated layer, described insulating barrier is coated with insulation screen, and insulation screen is coated with tincopper fuse wire braided armor becomes the insulation heart yearn; Three thoroughly do away with the edge heart yearn is provided with spaced earth connection, optical fiber cable, fiber filling in the slit on every side, and described earth connection, optical fiber cable, fiber are filled, three described insulation heart yearns are twisted into and are cable core; The intermediate gaps of described cable core is provided with filled core, and described cable core periphery is extruded with inner sheath, and inner sheath is coated with cotton synthetic fibre reinforced layer, and cotton synthetic fibre reinforced layer is extruded with oversheath outward.
2. port according to claim 1 machine writing that surpasses all the others dish cable in the Optical Fiber Composite, it is characterized in that: described brass wire diameter is 0.4mm.
3. machine writing that surpasses all the others dish cable in the Optical Fiber Composite in port according to claim 1 and 2 is characterized in that: lay ratio was 8~10 when described copper wire bundle twisted, and lay ratio was not more than 11 when described strand was stranded, and lay ratio was not more than 12 when described insulated electric conductor was stranded.
4. port according to claim 1 and 2 machine writing that surpasses all the others dish cable in the Optical Fiber Composite, it is characterized in that: described screen, insulation shielding layer material are flexible nonmetal semiconductive material.
5. port according to claim 1 and 2 machine writing that surpasses all the others dish cable in the Optical Fiber Composite, it is characterized in that: described inner sheath, jacket material are wear-resisting high-modulus neoprene.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN 201020686598 CN201904163U (en) | 2010-12-29 | 2010-12-29 | Optical fiber composite medium-voltage reeled cable used for port machinery |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN 201020686598 CN201904163U (en) | 2010-12-29 | 2010-12-29 | Optical fiber composite medium-voltage reeled cable used for port machinery |
Publications (1)
Publication Number | Publication Date |
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CN201904163U true CN201904163U (en) | 2011-07-20 |
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Application Number | Title | Priority Date | Filing Date |
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CN 201020686598 Expired - Fee Related CN201904163U (en) | 2010-12-29 | 2010-12-29 | Optical fiber composite medium-voltage reeled cable used for port machinery |
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Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN107680723A (en) * | 2017-09-30 | 2018-02-09 | 无锡市长城电线电缆有限公司 | A kind of carrying low voltage coaxial composite cable certainly |
-
2010
- 2010-12-29 CN CN 201020686598 patent/CN201904163U/en not_active Expired - Fee Related
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN107680723A (en) * | 2017-09-30 | 2018-02-09 | 无锡市长城电线电缆有限公司 | A kind of carrying low voltage coaxial composite cable certainly |
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Legal Events
Date | Code | Title | Description |
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C14 | Grant of patent or utility model | ||
GR01 | Patent grant | ||
CF01 | Termination of patent right due to non-payment of annual fee |
Granted publication date: 20110720 Termination date: 20141229 |
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EXPY | Termination of patent right or utility model |